World's First Self-curving Cornea Derived from Stem Cells

Scientists have developed a biological system which lets cells form a desired shape by moulding their surrounding material - initially creating the world's first self-curving cornea.

The cornea is the clear outer layer at the front of the eye ball.

In the research, a flat circle of gel containing corneal stromal cells (stem cells) was activated with a serum so that the edges of the gel contracted at a different rate to the centre, drawing up the edge over the course of 5 days to form a bowl-like curved cornea.

This time-lapsed video shows this astonishing process.

The video shows: The cornea moulding itself into a bowl-like structure over the course of 5 days. A three component gel comprising collagen, corneal stromal cells and peptide amphiphiles (inner circle) is combined with a two component gel comprising collagen and corneal stromal cells (outer circle). When triggered with a serum containing growth factors the outer ring of cells contracts more than the inner ring resulting in the progressive curvature of the structure. Credit: Wiley-VCH/Newcastle University

The research is published in Advanced Functional Materials and was led by Professor Che Connon, professor of tissue engineering, Newcastle University. He says: “Currently there is a shortage of donated corneas which has worsened in recent years, as they cannot be used from anyone who has had laser eye surgery so we need to explore alternatives such as these self-curving corneas.

“The cells are triggered into forming a complex 3D structure, but as this requires time to occur, the fourth dimension in this equation, we have labelled them 4D structures.”

The 4D formation is achieved by the innovative use of cells as biological actuators, components which get the parts moving. In this case, the cells themselves force the surrounding tissue to move in a pre-determined manner over time.

"The technology and understanding we have developed holds enormous potential as these corneas show that engineered tissue shape can be controlled by cell actuators." -Professor Che Connon, professor of Tissue Engineering

Remodeling the structure from the inside

"This is a cutting-edge example of the strict relationship between form and function as the research also showed that the biomechanical and bio-functional properties of these 4D structures reproduced those of the native tissue. -Dr Martina Miotto, lead author"

The gel, comprising collagen and encapsulated corneal cells, was laid out in two concentric circles. The formation of the curved shape which has a bowl-like structure was obtained by adding molecules called peptide amphiphiles to either one of the circles.

In one ring the active cells were pulling the internal structure of the gel (high contraction), in the other they were pulling these peptide amphiphile molecules (low contraction). This difference in contraction between the two concentric rings caused the curvature of the gel.

This happened because the cells preferred to bind to the peptide amphiphile molecules rather the internal structure of the gels.

Professor Connon added: “Because all the process was orchestrated by the cells themselves, we can envision them as bio-machines remodelling these structures from the inside."

“The technology and understanding we have developed holds enormous potential as these corneas show that engineered tissue shape can be controlled by cell actuators. This may lead us to imagine a future where such an approach can be combined with key-hole surgery enabling a surgeon to implant tissue in one shape which then develops into a more complex, functional shape within the body, driven by the behaviour of the cells themselves.”

Dr Martina Miotto, lead author on the paper explained: “This is a cutting-edge example of the strict relationship between form and function as the research also showed that the biomechanical and bio-functional properties of these 4D structures reproduced those of the native tissue, with undifferentiated corneal limbal epithelial stem cells located in the softer limbus and the differentiated epithelium spanning the stiffer centre of the anterior cornea.”

The team intend to take the work forward over the next few years with a view to refining the technique as a potential method of manufacturing corneas for human transplant.

This article has been republished from materials provided by Newcastle University. Note: material may have been edited for length and content. For further information, please contact the cited source.

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